Semiconductor device and its wiring method

ABSTRACT

A semiconductor device mounted on a mother board has a circuit board to be positioned on the mother board and a semiconductor chip positioned on the circuit board. The circuit board has a connection pad, a relay pad spaced away from the connection pad, and a wire connecting between the connection pad and the relay pad on a surface of the circuit board supporting the semiconductor chip. Also, the semiconductor chip has a connection pad corresponding to the connection pad formed on the circuit board. Further, the connection pad on the circuit board and the connection pad on the semiconductor chip are electrically connected to each other through a bonding wire.

FIELD OF THE INVENTION

The present invention relates to a semiconductor device to be mounted ona mother board and a wiring method for the semiconductor device. Inparticular, the present invention relates to a semiconductor device suchas chipset which includes a circuit board (daughter board) and one ormore chips each incorporating one or more semiconductor elements,wherein a connection pad on the chip is electrically connected withanother connection pad on the circuit board through a bonding wire, forexample. Also, the present invention relates to a method for wiring thesemiconductor device or chipset.

BACKGROUND OF THE INVENTION

In order to mount semiconductor devices or components such as chipsetsas many as possible on a limited area of a mother board, a variety ofstacked-chip package such as S-CSP (Stacked Chip Scale Package) andS-MCP (Multi Chip Package) have been provided in the art. Typically, thepackage includes a daughter board to be positioned on the mother boardand one or stacked plural semiconductor chips mounted on either or bothsurfaces of the daughter board.

FIGS. 11 and 12 illustrate an example of the conventional stackedpackage (S-CSP) generally indicated by reference numeral 100. Thepackage 100 includes a daughter board in the form of circuit board 102.The circuit board 102 is wired on its top surface with an electriccircuit including a plurality of connection pads or bonding pads 104(104 ₁-104 ₅) and is provided on its bottom surface with a number ofsolder balls 106 corresponding to the bonding pads 104, so that eachpair of bonding pad 104 and solder ball 106 is electrically connectedthrough a corresponding through-hole 108 formed in the circuit board102. The circuit board 102 bears first and second semiconductor chips110 and 112 manufactured through a well-known semiconductormanufacturing process and stacked in this order on the top surface ofthe circuit board 102. The first semiconductor chip 110 has bonding pads114 (114 ₂, 114 ₄) electrically connected with circuit elements formedin the chip. The second semiconductor chip 112 on the other handincludes another bonding pads 114 (114 ₁, 114 ₃, 114 ₅) electricallyconnected with electric elements formed in the chip. The bonding pads ofthe first and second semiconductor chips 110 and 112 are arranged sothat, when viewed from the Y-Y′ direction, the bonding pad 114 ₂positions between the bonding pads 114 ₁ and 114 ₃ and the bonding pad114 ₄ positions between the bonding pads 114 ₃ and 114 ₅. Also, thebonding pads 114 ₁-114 ₅ are electrically connected with thecorresponding bonding pads 104 (104 ₁-104 ₅) mounted on the circuitboard 102 through respective gold bonding wires. Then, the circuit board102 with the first and second semiconductor chips 110 and 112 soconstructed is sealed by a suitable resin so that the resin covers thechips 110 and 112 and boding wires 116. Thereby, the semiconductordevice is completed. It should be noted that the commercially availablesemiconductor device includes more bonding pads on the circuit boardand/or the first and second semiconductor chips; however, only a part ofwhich is illustrated in FIGS. 10 and 11 for the clarification of thosedrawings.

The above-described semiconductor device 100 in which the semiconductorchips 110 and 112 are electrically connected with the circuit board 102through bonding pads 104 and 114 mounted thereon and bonding wires 116extending between corresponding bonding pads requires the bonding pads114 ₁-114 ₅ of the semiconductor chips 110 and 112 and bonding pads 104₁-104 ₅ of the circuit board 102 to be arranged in this order in theX-X′ direction, respectively. Specifically, as shown in FIG. 12, thefive bonding pads 104 ₁-104 ₅ aligned in the X-X′ direction on thecircuit board 102 should be related with the bonding pads 114 ₁-114 ₅ onthe semiconductor chips 110 and 112. This is because that, when assumingthat the bonding pad 104 ₅ on the circuit board 102 is connected withanother bonding pad 114 ₁ on the semiconductor chip 112, positioned onthe opposite side with respect to the X-X′ direction, through thebonding wire 116, the bonding wire would cross and then make shortcircuits with another bonding wires.

However, in order to make an electrical connection between the circuiton the mother board and the electric component positioned on the motherboard, a practical requirement still exists in which, for example, thebonding pad 114 ₁ on the semiconductor chip 112 is connected with thebonding pad 104 ₅ on the circuit board 102. This can be attained bychanging the circuit pattern in the semiconductor chips 110 and 12according to the circuit patterns of the mother boards, whichdisadvantageously requires a variety of exposure masks for the circuitsof the chips.

SUMMARY OF THE INVENTION

Therefore, an object of the present invention is to provide asemiconductor device and its wiring method which allow the connectionpads on the semiconductor chips to be connected with correspondingelectrical connecting portions on the circuit board or daughter board,which would not subject to the restrictions imposed by the wire bonding.

Another object of the present invention is to provide a semiconductordevice capable of being mounted on a variety of mother boards withoutany need to change the circuit pattern of the semiconductor chips

Another object of the present invention is to provide a semiconductordevice which allows the circuit board to be electrically connected withthe semiconductor chips mounted on the board beyond a range in which thewire bonding can apply.

Accordingly, a semiconductor device mounted on a mother board comprisesa circuit board to be positioned on the mother board, and asemiconductor chip positioned on the circuit board. The circuit boardhas a connection pad, a relay pad spaced away from the connection pad,and a wire connecting between the connection pad and the relay pad on asurface of the circuit board supporting the semiconductor chip. Also,the semiconductor chip has a connection pad corresponding to theconnection pad formed on the circuit board. Further, the connection padon the circuit board and the connection pad on the semiconductor chipare electrically connected through a bonding wire.

The wire connecting between the connection pad and the relay pad on thecircuit board may be printed on the circuit board with the connectionpad and the relay pad.

Also, the wire connecting between the connection pad and the relay padon the circuit board may be a bonding wire.

Another semiconductor device comprises a first semiconductor chip havinga connection pad, a second semiconductor chip positioned on the firstsemiconductor chip, the second semiconductor chip having a connectionpad, wherein the electrode on the second semiconductor chip iselectrically connected with the connection pad on the firstsemiconductor chip.

The connection pad on the first semiconductor chip may be connected withthe connection pad on the second semiconductor chip through a bondingwire.

Also, the connection pad on the first semiconductor chip positions in aregion where the first semiconductor faces to the second semiconductorchip, the connection pad on the second semiconductor chip in the region,and the connection pad on the first semiconductor chip is electricallyconnected with the connection pad on the second semiconductor chipthrough a conductive member positioned in the region.

Another wiring method comprises the steps of:

providing a first semiconductor chip having a connection pad;

positioning a second semiconductor chip on the first semiconductor chip,the second semiconductor chip having a connection pad; and

electrically connecting between the connection pad of the firstsemiconductor chip and the connection pad of the second semiconductorchip.

The connection pad of the first semiconductor chip may be electricallyconnected with the connection pad of the second electrode through abonding wire.

Also, the connection pad on the first semiconductor chip positions in aregion where the first semiconductor faces to the second semiconductorchip and the connection pad on the second semiconductor chip positionsin the region, and the connection pad on the first semiconductor chip iselectrically connected with the connection pad on the secondsemiconductor chip through a conductive member positioned in the region.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a partial perspective view of a semiconductor device accordingto the first embodiment of the present invention;

FIG. 2 is side elevational view of the semiconductor device in FIG. 1;

FIG. 3 is a partial perspective view of a semiconductor device accordingto the second embodiment of the present invention;

FIG. 4 is a partial perspective view of a semiconductor device accordingto the third embodiment of the present invention;

FIG. 5 is a partial perspective view of a semiconductor device accordingto the fourth embodiment of the present invention;

FIG. 6 is a partial perspective view of a semiconductor device accordingto the fifth embodiment of the present invention;

FIG. 7 is a partial perspective view of a semiconductor device accordingto the sixth embodiment of the present invention;

FIG. 8 is a partial perspective view of a semiconductor device accordingto the seventh embodiment of the present invention;

FIG. 9 is a partial perspective view of a semiconductor device accordingto the eighth embodiment of the present invention;

FIG. 10 is a partial perspective view of a semiconductor deviceaccording to the ninth embodiment of the present invention;

FIG. 11 is a side elevational view of a stacked chip package (S-CSP) ofa conventional semiconductor; and

FIG. 12 is a perspective view of the stacked chip package in FIG. 11.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

With reference to the drawings, descriptions will be made to variouspreferred embodiments of the present invention. Note that in thefollowing discussions like reference numerals designate like parts orportions throughout the drawings.

Embodiment 1

FIGS. 1 and 2 illustrate respective parts of a semiconductor device ofthe first embodiment. The semiconductor device, generally indicated byreference numeral 10, is a semiconductor electric component such asarithmetic and memory devices to be mounted on a substrate or motherboard 12 together with similar semiconductor devices and other electriccomponents. The semiconductor device 10 includes a circuit board 14.Typically, the circuit board 14 employs a rectangular board (daughterboard) bearing certain circuits printed on its opposite surfaces. Also,the board is made of suitable insulator such as polyimide or the mixtureof glass and epoxy resin.

The circuit printed on the top surface of the circuit board 14 has aplurality of connection pad or bonding pads 16 _(X1), 16 _(X2), . . . 16_(Y1)′, 16 _(Y2), 16 _(Y3), . . . along and beside one edge of thecircuit board, extending in the X-X′ and Y-Y′ directions perpendicularto each other. Also, the board 14 bears a connection pad 18 spaced acertain distance away from the pad 16 _(Y1)′ (referred to as “relay pad”as necessary) in the Y-Y′ direction and a connecting wire 20 printed onthe board for the electrical connection between the relay pad 16 _(Y1)′and the connection pad 18. As shown in FIG. 2, the bottom surface of thecircuit board 14 holds a plurality of solder balls 22 for thecorresponding bonding pads 16 _(X1), 16 _(X2), . . . , 16 _(Y2), 16_(Y3), . . . and connection pad 18 except for the relay pad 16 _(X1)′.Also, the solder balls 22 are electrically connected with thecorresponding bonding pads 16 _(X1), 16 _(X2), . . . , 16 _(Y2), 16_(Y3), . . . and connection pad 18 through, for example, respectivethrough-holes 24 (see FIG. 2) extending between the top and bottomsurfaces of the circuit board 14.

The circuit board 14 supports the first semiconductor chip 26 on its topsurface. The first semiconductor chip 26 is designed to be smaller thanthe circuit board 14 so that a marginal portion of the circuit board 14supporting the electrodes exposes to air around the semiconductor chip26 as shown in FIG. 1. The first semiconductor chip 26 in turn supportsthe second semiconductor chip 30 on its top surface. The secondsemiconductor chip 30 is designed to be smaller than the firstsemiconductor chip 26 so that a marginal portion of the firstsemiconductor chip 26 exposes to air around the second semiconductorchip 30. The first and second semiconductor chips 26 and 30 may besecured on the circuit board 14 and the first semiconductor chip 26,respectively, by means of a suitable bonding material. Although not onlythe circuit board 14 but also the first and second semiconductor chips26 and 30 have rectangular plane configurations, they may have anotherplane configurations.

The first and second semiconductor chips 26 and 30 each have one or moresemiconductor elements such as transistor formed through thesemiconductor manufacturing process including several steps such as filmformation, etching, and exposure. In particular, the first semiconductorchip 26 bears connection pads or bonding pads 32 _(X1), 32 _(Y2), . . .along edges extending in the X-X′ and Y-Y′ directions. Likewise, thesecond semiconductor chip 30 bears bonding pads 32 _(X2), 32 _(Y1), 32_(Y2), . . . along edges extending in the X-X′ and Y-Y′ directions. Thebonding pads 32 _(X1), 32 _(X2), . . . , 32 _(Y1), 32 _(Y2), 32 _(Y3), .. . are located corresponding to the bonding pads 16 _(X1), 16 _(X2), .. . , 16 _(Y1)′, 16 _(Y2), 16 _(Y3), . . . on the circuit board 14.Specifically, for the bonding pads arranged along and beside the edgesextending in the Y-Y′ direction, the corresponding bonding pads 16_(Y1)′ and 32 _(Y1), 16 _(Y2) and 32 _(Y2), and 16 _(Y3) and 32 _(Y3)are positioned on respective lines extending in the X-X′ direction.Likewise, for the bonding pads arranged along and beside the edgesextending in the X-X′ direction, the corresponding bonding pads 16 _(X1)and 32 _(X1), 16 _(X2) and 32 _(X2), and 16 _(X3) and 32 _(X3) arepositioned on respective lines extending in the Y-Y′ direction.

It should be noted that the bonding pads 32 _(X1), 32 _(X2), . . . , 32_(Y1), 32 _(Y2), 32 _(Y3), . . . may be formed in the process of thesemiconductor manufacturing process or may be formed in another processby the use of a well known printing technique, for example. Also, afterthe first and second semiconductor chips 26 and 30 has been secured onthe circuit board 14, the bonding pads 32 _(X1), 32 _(X2), . . . , 32_(Y1), 32 _(Y2), 32 _(Y3), . . . are electrically connected withcorresponding bonding pads 16 _(X1), 16 _(X2), . . . , 16 _(Y1)′, 16_(Y2), 16 _(Y3), . . . by extending the bonding wires of goldtherebetween. Finally, although not shown, the semiconductor chips 26and 30, including bonding wires 34 and bonding pads, are covered with asuitable sealant made of insulator.

The semiconductor device 10 so constructed is positioned on the motherboard 12 which is generally far greater than the circuit board 14 andthen heated in a suitable furnace (not shown) such as reflow furnace formelting the solder balls. This causes the semiconductor chips 26 and 30to be secured and connected permanently with the circuit of the motherboard. Therefore, even though the bonding pad 32 _(X1) is offset fromthe bonding pad 32 _(Y1) in the Y-Y′ direction when the semiconductorchips 26 and 30 have been mounted on the circuit board 14, it iselectrically connected with the associated portion of the circuit board14 or connection pad 18 through the bonding pad or relay pad 16 _(Y1)′.This means that, simply by using the relay pad on the circuit board 14and without changing the circuit design (i.e., mask pattern) of thesemiconductor chip 30, the bonding pads of the semiconductor chips 26and 30 are suitably connected with the corresponding circuit portions onthe mother board. Accordingly, with the semiconductor device 10, nophysical contacts or interference with another bonding wires which hasbeen described above will be formed.

Second Embodiment

FIG. 3 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₂, according to the second embodimentof the present invention. In the semiconductor device 10 ₂, the circuitformed on the circuit board 14 includes a connecting bonding pad 16_(Y0) spaced a certain distance away from the relay pad 16 _(Y1)′ in theY-Y′ direction. The first semiconductor chip 26 bears relay pads 32_(Y1)′ and 32 _(Y0)′ spaced away from each other in the Y-Y′ directionand a connecting wire 36 extending between the relay pads 32 _(Y1)′ and32 _(Y0)′ for the electrical connection of the electrodes. The circuitboard 14 supports a solder ball (not shown) on the bottom surface of theboard so that the solder ball opposes the bonding pad 16 _(Y0). Thesolder ball and the opposing bonding pad 16 _(Y0) are electricallyconnected through a through-hole (not shown). Bonding wires 34 areextended between the connecting bonding pad 16 _(Y0) and the relay pad32 _(Y0)′, relay pads 32 _(Y1)′ and 16 _(Y1)′, and the relay pad 16Y₁′and the bonding pad 32 _(Y1) of the second semiconductor chip 30. Thiscauses an electrical connection between the bonding pad 32 _(Y1) and theconnecting bonding pad 16 _(Y0) shifted from the bonding pad 32 _(Y1) inthe Y-Y′ direction.

With the semiconductor device 10 ₂, similar to the first embodiment, thebonding pads of the semiconductor chips 26 and 30 can properly beconnected with the corresponding circuit portions on the mother board byproviding minor changes to the mask patterns of the semiconductor chip26 and the circuit board without providing any design change to thecircuit or relay pads on the circuit board 14. Also, even where no spaceremains for the wire 20 on the circuit board 14 as shown in FIG. 1, thephysical contact or interference of the bonding wires will be eliminatedby the transit wire on the semiconductor chip.

Third Embodiment

FIG. 4 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₃, according to the third embodimentof the present invention, which is a modification of the secondembodiment. In this embodiment, the bonding wire 34 is extended betweenthe bonding pad 32 _(Y1) of the semiconductor chip 30 and the relay pad32 _(Y1)′ of the semiconductor chip 26 and between the relay pad 32_(Y0)′ and the connecting bonding pad 16 _(Y0) of the circuit board 14,so that the bonding pad 32 _(Y1) is electrically connected with thebonding pad 16 _(Y0) which is shifted from the bonding pad 32 _(Y1) inthe Y-Y′ direction without any possibility of the interference of thebonding wires. Also, this embodiment only requires the relay pad orbonding pads on the second semiconductor chip 26. Further, no change isneeded for the mask pattern of the circuit board 14 or the secondsemiconductor chip 30. Furthermore, no bonding wire is required betweenthe relay pads 16 _(Y1)′ and 32 _(Y1)′, which renders the wire bondingmore simple and then inexpensive than that in the second embodiment.Besides, the total length of the bonding wire can be reduced. This inturn reduces an electric resistance in the circuit which would otherwisecause a signal delay to increase the rise and fall times of signals.

Fifth Embodiment

FIG. 5 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₄, according to the fifth embodimentof the present invention. In the semiconductor device 10 ₄, one bondingpad mounted on the semiconductor chip 30 beside its edge extending inthe Y-Y′ direction is electrically connected with another bonding padmounted on the circuit board 14 beside its edge extending in the X-X′direction.

Specifically, a relay pad 32 _(Y1)′ is formed on a portion of the topsurface of the semiconductor chip 26, beside its edge 38 extending inthe Y-Y′ direction, corresponding to the bonding pad 32 _(Y1) formed onthe top surface of the semiconductor chip 30, beside its edge 40extending in the same direction. Also, a relay pad 32 _(X0)′ is formedon the top surface of the semiconductor chip 26, beside its edge 42extending in the X-X′ direction, corresponding to the bonding pad 16_(X0) formed on the circuit board 14, beside its edge 44 extending inthe same direction. The relay pads 32 _(Y1)′ and 32 _(X0)′ areelectrically connected with each other through a connecting wire or line46 formed therein or thereon in the manufacturing process of thesemiconductor chip 26. The circuit board 14 has a solder ball (notshown) secured on its bottom surface and electrically connected with thebonding pad 16 _(X0) by a through-hole (not shown). The bonding wires 34are extended between the bonding pad 32 _(Y1) and the relay pad 32_(Y1)′ and between the relay pad 32 _(X0)′ and the connection pad 16_(X0), which causes the bonding pad 32 _(Y1) to be electricallyconnected with the bonding pad 16 _(X0) which is shifted both in theX-X′ and Y-Y′ directions.

With the semiconductor device 10 ₄, each pad can electrically beconnected with another pad which is shifted in the X-X′ and Y-Y′directions beyond a range in which a wire bonding can be applied.Therefore, each connecting portion of the semiconductor device can beconnected around to any portions of the mother board.

Although in this embodiment the connection pad positioned beside oneedge of the semiconductor chip is connected with another connection padpositioned beside another neighboring edge of the circuit board, it maybe connected with another connection pad positioned on the opposite sideof the board since the circuit can be wired freely in the circuit boardin the manufacturing process of the semiconductor device.

Fifth Embodiment

FIG. 6 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₅, according to the fifth embodimentof the present invention, which is a modification of the firstembodiment. In the semiconductor device 10 ₅, the relay pad 16 _(Y1)′formed on the circuit board 14 is electrically connected with theconnecting bonding pad 16 _(Y0) through the bonding wire 34. With thesemiconductor device 10 ₅, similar to the first embodiment, the bondingpad 32 _(Y1) can be connected with another bonding pad on the circuitboard which is shifted from the bonding pad 32 _(Y1) not only in theY-Y′ direction but also, by using another relay pad, in the X-X′direction.

Sixth Embodiment

FIG. 7 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₆, according to the sixth embodimentof the present invention, which is a modification of the secondembodiment. In the semiconductor device 106, a relay pad 32 _(Y0)′ isformed on the semiconductor chip 26. Also, the bonding wires 34 areextended between the bonding pad 32 _(Y1) of the semiconductor chip 30and the relay pad 16 _(Y1)′ of the circuit board 14, between the relaypad 16 _(Y1)′ on the circuit board 14 and the relay pad 32 _(Y0)′ on thesemiconductor chip 26, and between the relay pad 32 _(Y0)′ of thesemiconductor chip 26 and the connecting bonding pad 16 _(Y0) on thecircuit board 14. This causes the bonding pad 32 _(Y1) on thesemiconductor chip 30 to be connected with another bonding pad 16 _(Y0)on the circuit board which is shifted from the bonding pad 32 _(Y1) inthe Y-Y′ direction.

With the semiconductor device 10 ₆, the bonding pad 32 _(Y1) on thesemiconductor chip 30 can be connected with another bonding pad on thecircuit board 14 which is shifted spaced away from the bonding pad 32_(Y1) without any need to change the mask pattern of the semiconductorchip 30 and also without any interference of the bonding wires.

Seventh Embodiment

FIG. 8 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₇, according to the seventh embodimentof the present invention. In this semiconductor device 10 ₇, aconnection pad 52 _(Y1) of the semiconductor chip 30, which would beconnected to a connection pad 50 _(Y0) on the top surface of the circuitboard, is formed on the bottom surface of the semiconductor chip 30.Also, a top surface 56 of the semiconductor chip 26 supporting thesemiconductor chip 30 has a wire portion 58 formed on the surface 56 sothat, when the semiconductor chip 30 is placed on the semiconductor chip26, the connection pad 52 _(Y1) faces to the wire portion 58. The wireportion 58 is extended outwardly in the X-X′ direction and thenconnected with another wire portion 60 formed in a marginal regionsurrounding around a region where the semiconductor chip 30 wouldoccupy. The wire portion 60 is in turn connected through another wireportion 62 extending from the wire portion 60 in the X direction with arelay pad 64 also formed on the marginal region. The connection pad 52_(Y1) on the semiconductor chip 30 is connected with the wire portion 58by placing the semiconductor chip 30 onto the semiconductor chip 26 and,at that moment, by holding a solder 66 between the connection pad 42_(Y1) and the wire portion 58. The solder 66 is heated to melt in asubsequent process, which causes the semiconductor chip 30 to make aclose contact with the semiconductor chip 26. Then, the wire portion 64of the semiconductor chip 26 is electrically connected with theconnection pad 50 _(Y0) of the circuit board 14 through the bonding wire34.

With the semiconductor device 10 ₇, the connection pad on thesemiconductor chip, even though it is formed on the surface confrontingto the opposed semiconductor chip, can be wired to any connectingportion on the circuit board which is shifted from the connection pad inthe X-X′ and Y-Y′ directions without causing the interference of thebonding wires. Also, even when the upper semiconductor chip 30 coversmost of the opposing upper surface of the lower semiconductor chip 26,the wire can be extended in the X-X′ and/or Y-Y′ direction within thelimited marginal region in the top surface of the lower semiconductor.Further, the length of the bonding wire can be reduced, which in turnreduces time and cost for the wire bonding.

Although FIG. 8 shows one connection pad on the bottom surface of thesemiconductor chip 30, more connection pad or all the pat electrode maybe arranged on the bottom surface of the semiconductor chip 30. In thelatter instance, no connection pad exists on the top surface of thesemiconductor chip 30. This allows the connection pads to be connectedwith another connecting portions without using wire bonding and,thereby, reduces a height and then the size of the semiconductor device.

Of course, only a part of the number of electrodes, including theconnection pad 52 _(Y1), may be formed on the bottom surface of thesemiconductor chip with the remaining part of the connection padspositioned on the top surface of the semiconductor chip.

Also, although the solder is used for the connection of the opposingelectrodes on the semiconductor chips 26 and 30, it may be replaced byanother connecting technique.

Eighth Embodiment

FIG. 9 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₈, according to the eighth embodimentof the present invention, which is a modification of the seventhembodiment and is removed of wire portions 62 and 64 in the seventhembodiment shown in FIG. 8. Also, the circuit board 14 has connectionpads 70 _(Y0) and 70 _(Y1)′ formed thereon and spaced apart in the Y-Y′direction and a connection pad 72 connecting between the connection pads70 _(Y0) and 70 _(Y1)′. Further, the wire portion 60 and the connectionpad 70 _(Y1)′ are electrically connected to each other by the bondingwire 68. With the semiconductor device 10 ₈, the same advantages can beattained as the seventh embodiment.

Ninth Embodiment

FIG. 10 illustrates a part of the semiconductor device, generallyindicated by reference numeral 10 ₉, according to the ninth embodimentof the present invention, which is a modification of the eighthembodiment. In this semiconductor device 109, the connection pad 70_(Y0) and the relay pad 70 _(Y1)′ are electrically connected by thebonding wire 34. With the semiconductor device 10 ₉, the same advantagescan be attained as the seventh embodiment.

Other Modifications

Although in the previous embodiments the circuit board is made ofrectangular plate, it may be a lead frame which is made of conductiveplate and then formed into a certain configuration.

Also, although in the previous embodiments the circuit board supportsthe first and second semiconductor chips, the present invention is notlimited by the number of the semiconductor chips mounted on the circuitboard.

ADVANTAGES OF THE INVENTION

As can be seen from above, according to the present invention theconnection pads of the semiconductor chip can be connected with anyconnecting portions provided on the substrate without any restrictionimposed by the wire bonding and beyond the wiring capability of the wirebonding.

Also, the semiconductor device according to the present invention can bemounted on a variety of mother boards without any need to change itscircuit.

Further, the semiconductor device according to the present inventionallows the semiconductor chip to be connected with the circuit boardbeyond the range in which the wire bonding can apply.

1-9. (canceled)
 10. A semiconductor device, comprising: a circuit boardhaving a first pad; a first semiconductor chip mounted on a first planesurface of said circuit board and having a second pad and a connectionwire electrically connected the second pad; a second semiconductor chipmounted on a second plane surface of said first semiconductor chip so asto face a third plane surface thereof to the second plane, said secondsemiconductor chip having a third pad formed on the third plane surface,and a bonding wire jumping from the second pad over one edge of saidfirst semiconductor chip and reaching the first pad, wherein the secondpad is formed in an area of the second plane surface which is notcovered by said second conductor chip, and the connection wire is formedin said first semiconductor chip and electronically connected to thethird pad of said second semiconductor chip.